蟋蟀声信号演化的机制。

Vamsy Godthi, R. Balakrishnan, R. Pratap
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引用次数: 6

摘要

蟋蟀(灰蟋蟀科,灰蟋蟀亚科)通常发出载波频率在3-8千赫范围内的音调叫声。在这项研究中,我们探索了利用野外蟋蟀(Gryllus bimaculatus)鸣叫装置的有限元模型(FEM),基于谐振器几何和力学特性的实验测量,来预测其他8种野外蟋蟀的实测呼叫载波频率,范围在3到7 kHz之间。该模型可以根据谐振器的形态测量,准确预测所有8种物种的载流子频率,误差在几百赫兹以内。然后,我们利用该模型沿着谐振器尺寸和厚度的轴线探索了蟋蟀叫声载波频率的合理进化设计空间,并绘制了9种实验测量物种在该设计空间中的位置。虽然这9种蟋蟀的携带频率和体型在进化上是保守的,但它们都聚集在一个可用设计空间的小区域内。然后,我们探讨了这种明显的进化限制的原因,板球载波频率在下限和上限。我们发现,在较低的频率下,身体尺寸和声辐射效率是主要的限制因素,而在较高的频率下,使用发条机制的鸣声能量学可能会构成限制。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
The mechanics of acoustic signal evolution in field crickets.
Field crickets (Family Gryllidae, Subfamily Gryllinae) typically produce tonal calls with carrier frequencies in the range 3-8 kHz. In this study, we explored the use of a finite element model (FEM) of the stridulatory apparatus of a field cricket, Gryllus bimaculatus, based on experimental measurements of resonator geometry and mechanical properties, to predict the measured call carrier frequencies of eight other field cricket species, ranging between 3 and 7 kHz. The model allowed accurate predictions of carrier frequencies for all eight species to within a few hundred hertz from morphological measurements of their resonators. We then used the model to explore the plausible evolutionary design space for field cricket call carrier frequency along the axes of resonator size and thickness, and mapped the locations of the nine experimentally measured species in this design space. Although the nine species spanned the evolutionarily conserved spectrum of carrier frequency and body size in field crickets, they were clustered in a small region of the available design space. We then explored the reasons for this apparent evolutionary constraint on field cricket carrier frequencies at both the lower and higher limit. We found that body size and sound radiation efficiency were the main constraints at the lower limits, whereas the energetics of stridulation using the clockwork mechanism may pose a constraint at higher frequencies.
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